EP3018261A1 - Vip panel with surface corrugations, wall element and thermal insulation enclosure including such a panel - Google Patents

Abstract

The PIV-type heat-insulating panel (3) has an insulating core (1) including a porous, compressive material and a gas-tight barrier envelope (2) for maintaining an interior void and enclosing the insulating core. A flexible portion (5) of the envelope covers one of the main faces (4a) of the porous material and extends along a support surface to conform to a relief of this support surface, forming a hilly area with projections (5a) with rounded apex. The projections (5a) correspond to bosses of the support surface underlying the flexible portion (5). The bosses can be formed directly on the face (4a) of the porous material.

Description

The present invention relates to thermal insulation elements which comprise a porous core and a barrier envelope. The invention relates more particularly to insulating elementary panels, preferably PIV type (Vacuum Insulation Panel) and to a related manufacturing process. The invention also relates to a thermal insulation wall element for a building and an enclosure comprising such panels.

When it is desired to obtain high performance of wall insulation, the use of PIV panels is recommended.

As a reminder, the PIV-type elementary panels comprise an insulating porous core material (for example with an open-cell microcellular or nano-cell structure) kept under vacuum by a barrier envelope that guarantees gastightness. The barrier envelope is flexible and generally incorporates a heat-sealing film typically multilayer polymer / metal, most often using aluminum. These panels generally form plates of substantially constant thickness and have large sizes, for example 600 mm wide and 1200 mm long (other widths, for example 300, 400, 500 up to 1200 mm being of course available, the length generally varying between 500 and 2000 mm). The size of these panels is therefore suitable for the covering of building walls for thermal insulation purposes. In addition, the thermal performance of these elementary panels leads to thicknesses that can be reduced to minimize the bulk of the thermal insulation system, the thickness of a panel being less than 60 mm, and preferably less than 35 mm. mm.

In the field, super thermal insulators are termed materials having, at ambient temperature, a thermal conductivity level of less than 0.025 W m ^-1 K ^-1 . The PIV panels have a thermal conductivity (initial) lower than 0.007 W m ^-1 K ^-1 , and more preferably less than 0.005 W m ^-1 K ^-1 .

In the elementary panels of the PIV type, all the gases present are discharged from the porous material before vacuum packaging within a flexible barrier envelope, one of the main types of which consists (in a manner known per se) of a film multi-layer polymer / metal heat-seal, using metallized aluminum as a barrier which also makes it possible to avoid the formation of thermal bridges at the edges of the panel.

The use of such elementary panels to achieve an installation Thermal insulation is delicate because the barrier envelope (very thin) is fragile. This type of panel is sensitive to compression or bending forces that are likely to lengthen the envelope locally and to degrade its gas barrier properties. As a result, the use of PIV type panels has been limited.

As noted in the document US 5,858,501 , the barrier envelope is solicited from the manufacturing stage because of the narrowing of the core of porous material. This results in a crumpled surface appearance, with long crease lines or extensive digging (visible on the figure 4 of the document US 5,858,501 ).

It is known from this document to improve the aesthetic appearance of PIV panels. The panel has a surface grid, with a pitch that may be of the order of 6 cm, which results from grooves formed directly in the porous material, in this case a polymeric material with a foam structure (with open porosity). In practice, these grooves make it possible to take back part of the excess film forming the barrier envelope, in order to limit the appearance of wrinkles essentially at the level of the welds which are very damaging to the durability. If we consider the two main faces of the PIV panel, however, we always observe short wrinkles that appear on substantially the entire surface.

In practice, the inventors have observed, on the one hand, weaknesses at the intersections of the grooves, which form angular zones (with four vertices), and, on the other hand, risks of microscopic rupture of the barrier metallized layer due to the stresses. of shear imposed by the narrowing of the core formed by the porous material (with significant shrinkage in the sense of length and width), under the effect of atmospheric pressure. All this has adverse consequences on the longevity of the PIV panel (with a high insulation performance not maintained).

The document US 4517810 describes a panel that has a multilayer structure. The panel is flexible, which involves being able to compress the core material. The barrier layers are initially corrugated and it is this corrugated conformation that acts as a rigid mold for the flexible vacuum insulation element that defines the core layer. In contrast, in the PIV panels, the conformation of the core material (which is rigid) is fixed, so that the PIV panels are rigid because of the core material contained within the barrier envelope.

The present invention is intended to overcome all or part of the aforementioned drawbacks.

• un matériau poreux résistant à la compression, qui définit deux faces principales opposées et dont la plus petite dimension est une épaisseur maximale entre ces deux faces ; et
• une enveloppe barrière étanche aux gaz (plus souple que le matériau poreux) permettant de maintenir un vide intérieur et qui renferme le matériau poreux, l'enveloppe étant réalisée à partir d'au moins un film ou feuillet souple/déformable et présentant :
  • une première portion qui recouvre une première des deux faces principales, et
  • une deuxième portion qui recouvre une deuxième des deux faces principales,
• une première surface de support pourvue d'un relief, sous-jacente à la première portion de l'enveloppe barrière ;

avec la particularité que la première surface de support présente des ondulations en formant des bossages vers l'extérieur, chacun à sommet arrondi, la première portion de l'enveloppe barrière s'étendant le long de la première surface de support pour se conformer selon ledit relief avec des projections à sommet arrondi en correspondance avec les bossages.For this purpose, it is proposed according to the invention a thermo-insulating panel of the type PIV, comprising:

• a porous material resistant to compression, which defines two opposite major faces and whose smallest dimension is a maximum thickness between these two faces; and
• a gas-tight barrier envelope (more flexible than the porous material) for maintaining an internal vacuum and which encloses the porous material, the envelope being made from at least one flexible or deformable film or sheet and having:
  • a first portion which covers a first of the two main faces, and
  • a second portion covering a second of the two main faces,
• a first support surface provided with a relief, underlying the first portion of the barrier envelope;

with the particularity that the first support surface has corrugations forming outward bosses, each with a rounded apex, the first portion of the barrier envelope extending along the first support surface to conform to said relief with projections with rounded apex in correspondence with the bosses.

Thanks to these provisions, the material (typically a film) of the barrier envelope is guided in bending by the bosses, which significantly reduces the risk of micro-rupture / degradation by shear, which is particularly important on larger faces . The external envelope of the PIV-type panel remains perfectly intact when it is put under atmospheric pressure.

Specifically, when the pressure is increased around the envelope towards the end of the PIV panel design, the first portion of the envelope is first in contact with the rounded corners before continuing to apply (under the effect of the pressure exerted on the external side). The bosses form indeed the proximal portions of the first support surface which are therefore the first to engage against the inner face of the first portion. Deployment of this first portion, under the effect of pressure, is made towards the bottom of the distal portions which form cavities (concave areas between the bosses). The convex curvature of the bosses makes it possible to guide the first portion in flexion, which limits the risk of rubbing and stretching the material of the barrier envelope excessively against areas of the relief. In practice, the radius of curvature remains significant and there is no significant folding zone (not a fortiori folding with an angle close to 90 °).

It is understood that PIV insulating panels have a barrier envelope that marries the underlying surface by filling cavities without angular or brutal boundaries. In addition, wrinkles tend to be eliminated at least at the areas of curvature that extend between the peaks (bosses tops) and the low points (bottom cavities).

The PIV panel can be used in many applications and can have, if necessary, a global curvature to adapt to geometry constraints.

According to a particular feature, the first support surface has, in addition to the bosses, series of cavities, two adjacent cavities of the same series joining by a junction zone having a convex curvature in at least one direction that makes it possible to progressively reduce the depth of each of the cavities from a central zone which corresponds to a maximum depth of the cavity considered. Thus, neck areas are formed between the cavities by avoiding forming edges or angles that promote shearing effects.

• des creux d'une profondeur déterminée qui coïncident avec des cavités de la première surface de support, qui définissent le niveau inférieur des trois niveaux ;
• les projections, adjacentes aux creux et séparant deux séries de creux, qui définissent le niveau supérieur des trois niveaux ; et
• des cols moins profonds que les creux, séparant deux des projections, et définissant un niveau intermédiaire des trois niveaux (on comprend que ces cols coïncident chacun avec une des zones de jonction).

According to another feature, the first portion of the barrier envelope defines at least three surface levels, with:

• voids of a determined depth which coincide with cavities of the first support surface, which define the lower level of the three levels;
• the projections, adjacent to the hollows and separating two series of hollows, which define the upper level of the three levels; and
• necks shallower than the hollows, separating two projections, and defining an intermediate level of the three levels (it is understood that these passes each coincide with one of the junction areas).

• les projections affleurent au niveau d'un même plan tangent (plan virtuel).
• la première surface de support définit une surface apparente (typiquement parallèle au plan tangent) telle que perçue en deux dimensions sans prendre en compte le relief et une surface développée qui prend en compte le relief, sachant que la surface développée est supérieure d'au moins 2% à la surface apparente, et de préférence supérieure d'un pourcentage compris entre 3 et 6% par rapport à la surface apparente.
• la différence entre le niveau supérieur et le niveau inférieur est comprise entre 0,3 et 2 mm et est inférieure à la distance d'espacement entre les sommets respectifs de deux projections adjacentes.
• les deux faces principales sont préférentiellement parallèles et chacune des séries de cavités s'étend selon une même direction générale, de sorte qu'on obtient une configuration en quinconce des bossages et une configuration en quinconce pour les cavités.
• chacune des cavités présente un centre correspondant à un maximum local de profondeur, la première surface de support vérifiant la relation suivante : $$\mathrm{2}\le \mathrm{\lambda }/\mathrm{h}\le \mathrm{15}$$
  
  
  h représentant une amplitude maximale du relief mesurée perpendiculairement aux deux faces principales et exprimée en millimètres, et
  λ représente un écartement entre deux centres de cavités adjacentes séparées par un bossage (de sorte que cet écartement peut correspondre à une longueur d'onde lorsque l'alternance entre les bossages et les cavités définit une sinusoïde), cet écartement qui peut être constant étant exprimé en millimètres, mesuré suivant une direction qui est perpendiculaire à la direction utilisée pour mesurer l'amplitude h (ce ratio étant inférieur à 15 et de préférence inférieur ou égal à 10, il est représentatif du maillage resserré formé par les séries de cavités sachant que l'amplitude h est typiquement inférieure à 2 mm ; un tel ratio permet également d'éviter de former des rayons de courbure trop réduits).
• la première surface de support s'étend entre deux extrémités opposées du panneau, les bossages étant distribués de façon à ce que le relief s'étende entre lesdites deux extrémités opposées du panneau.
• les bossages sont distribués selon des rangées, suivant une direction déterminée, la première surface de support ayant suivant cette direction déterminée une forme sinusoïdale avec une alternance de tronçons courbes convexes et de tronçons courbes concaves (cette configuration est optimale pour éliminer le risque de microfissures).
• soit la première surface de support est définie par l'une au moins des deux faces principales du matériau poreux, soit elle est définie par une couche intermédiaire distincte du matériau poreux et plus mince que le matériau poreux.
• lorsqu'une couche intermédiaire est prévue, on peut prévoir que celle-ci est une couche perforée ou poreuse qui résiste à la compression et présente intrinsèquement les bossages ou que cette couche perforée ou poreuse est souple avec le relief sur la première surface de support qui résulte de l'empreinte formée sur la face principale sous-jacente du corps poreux résistant à la compression.
• la première surface de support présente des ondulations dans deux directions transverses l'une par rapport à l'autre ; avec cette disposition, chacun des bossages appartient à et forme une intersection de deux rangs de bossages.
• le panneau comporte une deuxième surface de support pourvue d'un relief, sous-jacente à la deuxième portion de l'enveloppe barrière.
• chacune des première et deuxième surfaces de support est dépourvue de surfaces planes, le panneau ayant un format parallélépipédique, de préférence à section rectangulaire.
• l'amplitude maximale du relief est inférieure à 3 mm (ce qui rend plus difficile la formation de replis).

In various embodiments of the panel according to the invention, one can optionally also resort to one and / or the other of the following provisions:

• the projections are exposed at the level of the same tangent plane (virtual plane).
• the first support surface defines an apparent surface (typically parallel to the tangent plane) as perceived in two dimensions without taking into account the relief and a developed surface which takes into account the relief, knowing that the developed surface is greater than at least 2% at the apparent surface, and preferably greater than a percentage between 3 and 6% with respect to the apparent surface.
• the difference between the upper level and the lower level is between 0.3 and 2 mm and is smaller than the spacing distance between the respective vertices of two adjacent projections.
• the two main faces are preferably parallel and each series of cavities extends in the same general direction, so that a staggered configuration of the bosses and a configuration in staggered for the cavities.
• each of the cavities has a center corresponding to a local maximum depth, the first support surface satisfying the following relation: $$\mathrm{2}\le \mathrm{\lambda }/\mathrm{h}\le \mathrm{15}$$
  
  
  h representing a maximum amplitude of the relief measured perpendicularly to the two main faces and expressed in millimeters, and
  λ represents a spacing between two adjacent cavities centers separated by a boss (so that this spacing may correspond to a wavelength when the alternation between the bosses and the cavities defines a sinusoid), this spacing which can be constant being expressed in millimeters, measured in a direction that is perpendicular to the direction used to measure the amplitude h (this ratio being less than 15 and preferably less than or equal to 10, it is representative of the constricted mesh formed by the series of cavities knowing that the amplitude h is typically less than 2 mm, such a ratio also makes it possible to avoid forming too small radii of curvature).
• the first support surface extends between two opposite ends of the panel, the bosses being distributed so that the relief extends between said two opposite ends of the panel.
• the bosses are distributed in rows, in a determined direction, the first support surface having in this direction determined a sinusoidal shape with an alternation of curved convex sections and concave curved sections (this configuration is optimal to eliminate the risk of microcracks) .
• either the first support surface is defined by at least one of the two main faces of the porous material, or it is defined by a separate intermediate layer of the porous material and thinner than the porous material.
• when an intermediate layer is provided, it can be provided that this is a perforated or porous layer which resists compression and intrinsically presents the bosses or that this perforated or porous layer is flexible with the relief on the first support surface which results from the imprint formed on the underlying main face of the porous body resistant to compression.
• the first support surface has corrugations in two transverse directions with respect to each other; with this arrangement, each of the bosses belongs to and forms an intersection of two rows of bosses.
• the panel has a second support surface provided with a relief, underlying at the second portion of the barrier envelope.
• each of the first and second support surfaces is devoid of planar surfaces, the panel having a parallelepipedal format, preferably of rectangular section.
• the maximum amplitude of the relief is less than 3 mm (which makes it more difficult to form folds).

• former une première surface de support avec un relief, par transcription d'un relief avec ondulations présent sur une plaque ou un rouleau, de sorte que la première surface de support présente des bossages vers l'extérieur, chacun à sommet arrondi, la première surface de support étant choisie parmi une surface d'une face principale de la plaque de matériau poreux et une surface principale d'une couche intermédiaire distincte du matériau poreux ;
• pendant une mise sous vide postérieure à la formation du relief, envelopper la plaque de matériau poreux et recouvrir la première surface de support, directement ou indirectement, par une enveloppe barrière étanche aux gaz permettant de maintenir un vide intérieur ; et
• soumettre à une pression atmosphérique l'extérieur de l'enveloppe, ce grâce à quoi une portion de l'enveloppe barrière s'étend le long de la première surface de support et se conforme selon un relief avec ondulations résultant d'un contact avec le relief pour former une face principale du panneau pourvue de projections.

There is also provided a method of manufacturing a PIV-type thermal insulating panel, using a plate of the porous, compressive-resistant material and comprising the steps of essentially:

• forming a first support surface with a relief, by transcribing a corrugated relief present on a plate or a roller, so that the first support surface has outwardly raised bosses, each with a rounded apex, the first surface support member being selected from a surface of a main face of the porous material plate and a major surface of an intermediate layer distinct from the porous material;
• during evacuation subsequent to the formation of the relief, wrap the plate of porous material and cover the first support surface, directly or indirectly, with a gas-tight barrier envelope to maintain an internal vacuum; and
• subjecting the outside of the envelope to atmospheric pressure, whereby a portion of the barrier envelope extends along the first support surface and conforms to a corrugated relief resulting from contact with the relief to form a main face of the panel provided with projections.

The method advantageously makes it possible to form PIV panels without significant additional cost. It is permissible to use a conventional product for the film or sheet (s) of the barrier envelope and the porous material forming the core is little modified. It may consist of compressed silica with the imprint adapted to form the relief or it may remain unchanged (in the latter case, an intermediate layer is used).

Of course, the expression "rounded top" does not exclude the presence of a substantially planar upper face with very small dimensions (reduced in size relative to the extent of the boss, for example, and in a nonlimiting manner, less 1 mm ² surface for the upper face of a boss having a base perimeter greater than 4 mm), knowing that this does not have the effect of creating a significant folding zone for the envelope. It is understood that the rounding of the vertex makes it possible to remove the sharp edges in the upper zone of the boss (by limiting or eliminating the angles), with a curved profile of the boss from its base to a junction zone typically tangential with the upper face. The roundness is similar to what is perceived for a hill (and not comparable to the topographic relief of a plateau bordered by a cliff or steep).

It is also proposed a thermally insulating wall element for building, which incorporates a plurality of panels according to the invention glued or fixed by means of a rigid frame in at least one thermal insulation layer. Such an element may advantageously have a smaller footprint if one compares with conventional components that do not have such a good thermal insulation performance.

In order to optimize the internal volume in electrical equipment (household appliances or the like), an enclosure is also proposed, for example for an electric appliance or for a refrigerated vehicle, provided with cooling or heating means, intended to thermally isolate a volume interior, comprising a bottom wall, a side wall and an upper wall, the enclosure comprising at least one panel according to the invention forming part of one of the bottom wall, the side wall and the upper wall.

• la figure 1 est une vue de face montrant une forme de réalisation d'un panneau de type PIV conçu selon un premier mode de réalisation de l'invention, avec le matériau poreux du coeur qui apparaît du fait d'une découpe en bas à gauche ;
• la figure 2A est une vue schématique illustrant le relief formé sur la première surface de support, avec des bossages à sommet arrondi définissant les points culminants et des cavités définissant les points bas
• la figure 2B est une vue schématique illustrant un type de relief similaire à celui de la figure 2A, formé sur la première surface de support, avec des bossages à sommet arrondi définissant les faces culminantes et des cavités définissant les points bas ;
• les figures 3A et 3B sont des vues de détail en coupe longitudinale, qui montrent le positionnement relatif d'une première portion de l'enveloppe barrière par rapport à la première surface de support, respectivement avant et après mise sous pression du côté externe du panneau ;
• la figure 4 illustre en perspective un relief utilisé dans une forme de réalisation préférée de l'invention, avec une structure de surface sinusoïdale selon les deux directions perpendiculaires (typiquement longueur et largeur) du panneau PIV ;
• la figure 5 est une vue en coupe d'un équipement pouvant être utilisé pour former par compression le matériau poreux formant le coeur du panneau de la figure 1, avec des ondulations en surface ;
• la figure 6 est une vue en coupe montrant un panneau PIV conçu selon un deuxième mode de réalisation de l'invention ;
• la figure 7 est un schéma montrant en coupe un réfrigérateur incluant une enceinte délimitée par des panneaux PIV conformes à l'invention ;
• la figure 8 montre une vue en coupe verticale d'une forme de réalisation d'un système de doublage de paroi utilisant des panneaux de la figure 1.

Other features and advantages of the invention will emerge during the following description of several of its embodiments, given by way of non-limiting examples, with reference to the accompanying drawings in which:

• the figure 1 is a front view showing an embodiment of a PIV-type panel designed according to a first embodiment of the invention, with the porous material of the core which appears due to a cut-out at the bottom left;
• the Figure 2A is a schematic view illustrating the relief formed on the first support surface, with round-headed bosses defining the highlights and cavities defining the low points
• the Figure 2B is a schematic view illustrating a type of relief similar to that of the Figure 2A formed on the first support surface, with rounded apex bosses defining the rising faces and cavities defining the low points;
• the Figures 3A and 3B are detailed views in longitudinal section, which show the relative positioning of a first portion of the barrier envelope with respect to the first support surface, respectively before and after pressurizing the outer side of the panel;
• the figure 4 illustrates in perspective a relief used in a preferred embodiment of the invention, with a sinusoidal surface structure in the two perpendicular directions (typically length and width) of the PIV panel;
• the figure 5 is a sectional view of equipment that can be used to compress the porous material forming the core of the panel of the figure 1 , with undulations on the surface;
• the figure 6 is a sectional view showing a PIV panel designed according to a second embodiment of the invention;
• the figure 7 is a diagram showing in section a refrigerator including an enclosure delimited by PIV panels according to the invention;
• the figure 8 shows a vertical sectional view of an embodiment of a wall-doubling system using panels of the figure 1 .

In the different figures, the same references designate identical or similar elements. The dimensions in the direction of the thickness have been voluntarily exaggerated in certain figures to improve the visibility of the different layers and / or relief.

As illustrated on figures 1 and 3A-3B , the insulating core 1, porous, of the panel 3 is evacuated and enclosed in the barrier envelope 2 which is preferably flexible. The envelope 2, sealed, has a gas barrier effect and thus maintains the vacuum in an interior volume. The envelope is made from at least one film or flexible sheet. Of course, the panel 3 is here provided without mechanical protection, the barrier envelope 2 defining the outer layer of the panel 3. The insulating core 1 comprises a porous material 3a resistant to compression whose volume may correspond to the volume of the barrier envelope 2.

When the barrier envelope 2 comprises two portions in the form of a thin film, they may be welded on themselves or at least on a thin film-deposited filler material. Each of the two portions 5, 7 may comprise one or more polymer layers and one or more metallic or mineral high barrier layers. Among the polymers used, there may be mentioned EVOH (ethylene vinyl alcohol) copolymers, PVDC, PET, PP, all metallized or combined with aluminum strips. In the latter case, the surface polymer layers allow thermal welding and the polymer core layers ensure, with typically aluminum films, perfect gas tightness.

In a manner known per se, the barrier envelope 2 is in intimate contact with two large opposite support surfaces, and may also be in contact with a lateral surface defined by the slices of the panel 3 (for example four slices when the insulating core 1 has a parallelepipedal format, preferably rectangular section). However, it is intended here that at least one of the supermarkets of support 21, 21 ', 23 has a relief R, so that the barrier envelope 2 has similar corrugations or variations.

On the figures 1 and 3B , one can thus see a main external face F1 of the panel 3 whose surface is defined by a first portion 5 of the barrier envelope 2 and has corrugations 6. The first portion 5 covers the insulating core 1 at least in the area rectangular corresponding to one of the main faces 4a of the porous material 3a.

With reference to figures 1 and 8 it is understood that the porous material 3a defines two opposite main faces 4a and 4b, typically rectangular and has a smaller thickness e. The thickness e, here the smallest dimension, is defined as a maximum thickness between the two faces 4a and 4b. The thickness e of the porous material 3a may for example be less than 60 mm, preferably less than or equal to 35 mm. It is understood that the porous material 3a preferably defines at least 90% of the total thickness of the PIV type panel 3, knowing that the barrier envelope 2 consists of a very thin waterproof film whose thickness is much smaller than 1 mm, and typically less than 0.2 mm.

The exact nature of the porous material 3a can vary as needed. It will be understood that the invention does not relate to the physico-chemical constitution of the insulating core 1 and rather targets a geometry that prevents the appearance of microcracks in the barrier layers of the envelope 2, at least on the first main external face F1, and preferably also on the second opposite main external face F2 (cf. figure 8 ). By way of non-limiting example, mention may be made of a porous material 3a based on fumed silica, silica airgel or powdery material with similar insulating properties. In a manner known per se, such a porous material 3a is rigid, so that the PIV panel is not adapted to match the conformation of an outer layer. On the other hand, it is permissible to manufacture a format of porous material with corrugations on at least one of its main faces 4a, 4b. If necessary, the panel 3 may have an overall curvature that does not oppose rigidity. The deviation from the flatness on the main faces 4a and 4b then comes from an initial conformation of the porous material 3a, and not from the barrier envelope 2 which is thinner and flexible.

To increase the performance of the panel 3, a desiccator or at least one adsorption and absorption material (getter) may be added inside the insulating core 1 to absorb residual water vapor and atmospheric gases. . In the case of a surface getter, it may have a texture that forms all or part of the relief R.

The hilly appearance of the surface of the barrier envelope 2, at least in portions 5 and 7 covering the main faces 4a and 4b is illustrated in particular in the Figures 3B , 4 , 6 and 8 .

With reference to figures 1 , 3B , 4 and 6 the first portion 5 has protruding projections 5a with a rounded apex and valleys 8 extending between four projections 5a. Arrow F on the figure 1 indicates a general direction of projection alignment 5a. According to this same general alignment direction, the troughs 8 are distributed in parallel series 9, as clearly visible on the figure 4 . The projections 5a, here in the form of complementary ridges of the valleys 8 (valleys), each have a rounded vertex which has a convexity. In the embodiment of the figure 4 this convexity is such that the culminating part is not plane.

However, it is understood that the culminating part is not necessarily point and may optionally define a substantially flat upper face 30a (non-point). The periphery of the projection 5a in this case forms a single lateral surface (avoiding forming flanks joined by edges) and connects with a convex upper annular portion to the upper face (with a substantially tangential connection profile). Thus the contour of the upper face 30a does not form an annular ridge (no protruding edge), as illustrated schematically on the Figure 2B .

In a preferred embodiment, the projections 5a are flush at the same tangent plane P (virtual plane). The figure 4 illustrates such a plane P. The fact of keeping the same level L3 for the rounded vertices results from the formation of the bosses 30. As represented on the Figures 3A-3B having a single level for the rounded top of the bosses 30 ensures that the contact between all the bosses 30 and the portion 5 of the barrier envelope 2 is simultaneously. It is preferable to avoid the presence of an isolated boss which would be more salient than the other bosses 30. In variants with a tight mesh of the bosses, it is however possible to use bosses of different levels, by evenly distributing the bosses higher level to minimize the maximum distance between two such higher level bosses.

• les creux 8 d'une profondeur déterminée (ici identique), qui définissent le niveau inférieur L1 ;
• les projections 5a à sommet arrondi, adjacentes aux creux 8 et séparant deux séries 9, qui définissent le niveau supérieur L3 ; et
• des cols 10 moins profonds que les creux 8, séparant deux des projections 5a, et définissant un niveau intermédiaire L2.

The first portion 5 of the barrier envelope 2 can define several surface levels by marrying the relief R of a first support surface 21, 21 '(underlying the first portion 5). The figure 4 shows that at least three surface levels L1, L2, L3 are defined by the first portion 5, with:

• the recesses 8 of a determined depth (here identical), which define the lower level L1;
• the projections 5a with rounded apex, adjacent to the recesses 8 and separating two series 9, which define the upper level L3; and
• necks 10 shallower than the recesses 8, separating two projections 5a, and defining an intermediate level L2.

It may be noted that the L2 level can be here the same for all the necks 10. However, it is also possible to predict level differences between the necks 10, knowing that the lateral spacing between two projections 5a can optionally vary. The difference between the upper level L3 and the lower level L1 may be between 0.3 and 2 mm, and preferably less than the spacing distance between the respective vertices of two adjacent projections 5a. This allows the portions 5, 7 to cover the corresponding support surface 21, 21 'and respectively 23 with a progressive descent towards the central areas 41 of the cavities 40.

With reference to Figures 2A-2B , 3A and 4 , the maximum difference in height of the portion 5 here corresponds substantially to the maximum amplitude h of the relief R defined by the first support surface 21 (visible Figures 2A-2B ). The maximum amplitude h of the relief R is measured perpendicular to the two main external faces F1, F2 which extend parallel to each other. It is understood that the maximum amplitude h is here typically less than or equal to 2 mm to limit local bending of the barrier envelope 2.

On the Figures 2A-2B , the first support surface 21 is here formed directly by the main face 4a of the porous material 3a. The second support surface 4b may be similarly formed by the porous material 3a.

With reference to Figures 2A-2B , the relief R of the first support surface 21 defines a developed surface greater than the apparent surface as perceived in two dimensions (surface of the same perimeter, without taking into account the relief R). The surface excess for the developed surface may be at least 2% of the apparent area. Preferably, this surplus represents a percentage of between 3 and 6% of the apparent surface (virtual flat surface here in the case of a parallelepipedal format). It is understood that this surplus substantially corresponds to the surface of the excess portion 5 after the narrowing of the insulating core 1.

The figure 5 illustrates a non-limiting example of equipment 13 for forming by compression the porous material 3a constituting the core of the panel 3. The corrugations 6 at the surface, on each side of the panel 3 result from the imprint present on the two compression plates 14 and 15. A guiding device with guides 16 makes it possible to adjust the thickness e desired for the porous material 3a forming the insulating core 1. The compression plate 15 is for example mobile in the enclosure 17 molding to allow to operate with the desired thickness e. Pressing members 18 (here two bodies) allow to bring the compression plates 14 and 15. It is understood that the equipment 13 can simultaneously form a relief R on the face 4a and on the face 4b. Each of these faces 4a and 4b is then then, directly or indirectly, covered by the first and second portions 5 and 7 of the barrier envelope 2, as illustrated by the succession of Figures 3A and 3B .

The compression plate may have a larger dimension to abut on an annular edge of the enclosure 17. The perimeter of the plate forming the porous material 3a is delimited by a side wall of the enclosure 17 which extends from a support member 19 substantially planar. The side wall of the enclosure 17 extends from this support member 19 to the annular edge and a movable arm of the pressing members 18 passes through the support member 19. This movable arm serves to drive the relative displacement by translation of the compression plate 15 with respect to the base of the side wall 17.

Dust evacuation devices may optionally be provided at the compression plates 14 and / or 15. Of course, other configurations may be used to define one or two support surfaces 21, 22 directly on the faces. main 4a, 4b porous material 3a. The relief R is preferably similar on these two faces 4a, 4b, and extends over at least 90% of the face considered, preferably 100% which means, in the illustrated non-limiting example of Figures 2A and 4 , that the flat areas are completely deleted.

With reference to Figures 2A-2b it will be understood that rounded-top bosses 30 are formed on the first support surface 21. Thus, texturing the first support surface 21 provides a real deployed surface for contact with the barrier envelope 2 which compensates for the removal of the porous material 3 forming the core. This thus considerably reduces the shear stresses affecting the layer or layers of the barrier envelope 2. Of course, it is preferable to texture in this way the two main faces 4a, 4b of the porous material when designing the barrier envelope. 2 using films or leaflets on both sides.

When using a solution of the type illustrated in figure 5 it is understood that the first support surface 21 with its relief R is obtained by transcription of a corrugated relief present on a complementary rigid member, for example a plate or a roller.

During evacuation, the gastight barrier envelope 2 is affixed to wrap the porous material plate 3a and cover the first support surface 21, directly or indirectly. Stopping the vacuum has the effect of the outside of the casing 2 at an external pressure (atmospheric pressure). As a result, the material of the flexible envelope 2 is bent in the areas not supported by the bosses 30. In practice, the retraction of the porous material 3a of the insulating core 1 and the insertion into the cavities 40 These inflected zones, in the form of valleys, include the troughs 8 and the collars 10 illustrated on FIG. figure 4 .

More generally, the portion 5 of the barrier envelope 2, which extends along the first support surface 21, 21 ', conforms to the corrugated relief 6 as soon as the evacuation is stopped, while maintaining its function of gas tightness. At least one main face F1, F2 of the panel 3 is thus formed with a hilly appearance that takes up the undulations 6 of the corresponding support surface 21 or 23. As shown in FIGS. Figures 2A-3A , the first support surface 21 obviously retains its external geometry with the same relief R, which is the same before and after the introduction of the barrier envelope 2 more flexible than the underlying layer.

With reference to figures 1 and 4 it can be seen that the projections 5a can cover substantially half of the apparent surface defined within the perimeter of the outer face F1. An elemental pattern of the hilly area may typically have a center projection 5a and a fraction of the four adjacent hollows at the four corners of this pattern. It is understood that the projections 5a can thus be distributed in staggered rows. Each fraction here corresponds substantially to a quarter of a hollow 8 (which means that the recesses 8 and the projections 5a define substantially the same surface). Alternatively, however, the wavelength can be modulated in a series 9 differently from the perpendicular series, for example to accommodate the behavior of porous material 3a during shrinkage.

Although the illustrated example on Figures 1-3B and 5 shows that the first support surface 21 is defined by at least one of the two main faces 4a, 4b of the porous material 3a, it is understood that one can also add a flexible intermediate layer without barrier effect which has the same conformation with corrugations 6 that the face of the porous material 3a it covers. In this case, the support surface is distinct from the porous material 3a and is formed by an additional layer which is also porous or provided with holes. The conformation of the figure 4 or similar conformation for the portion 5 can thus be obtained without direct contact with the face 4a with relief of the porous material 3a (which case remains similar to that of the figure 3B but with a thin underlay along the portion 5).

In the embodiments set out above, the relief R on the first support surface 21 typically results from the imprint formed on the main face. 4a, 4b underlying the porous body 3a resistant to compression. The transfer of the impression can be made other than by compression, the use of calenders engraved with relief may for example be another transfer option. It is understood that differently shaping the porous material 3a does not affect the rest of the manufacturing process.

Alternatively, the first support surface 21 'can be formed as shown in FIG. figure 6 . In this case, the first support surface 21 'is defined externally to the porous material 3a, by an intermediate layer 26 which is typically thinner than the porous material 3a. The intermediate layer 26 is flexible (here without barrier effect) and may have localized perforations 28. The bosses 30 are intrinsically formed by this intermediate layer 26, the main face 4a of the porous material 3a being substantially flat. In this example, a porous block of mineral material such as silica or polymer can be used to define the insulating core 1. The intermediate layer 26 which defines the relief pattern can envelop the porous block, preferably entirely. In the case of figure 6 it is understood that the first support surface 21 'is not folded because it is more rigid than the barrier envelope 2 and, preferably, more rigid than the intermediate layer 26.

In practice, it is possible, for example, to interpose an embossed film or a fabric between the porous material 3a forming the core of the panel 3 and the barrier envelope 2. In this case, this film forming the intermediate layer 26 can serve to contain the dust generated. It can obviously be perforated or porous to ensure a good vacuum. Thermoplastic films in PE, PET, PP, etc. in particular are usable. A fabric, defining a continuous layer and / or without significant folding angles, can also be used to form bosses 30 and cavities 40.

It is understood that the bosses 30 alternate with cavities 40 on the first support surface 21, 21 'so that the outside of the panel 3 has corrugations 6. The bosses 30 can be distributed in rows, in a determined direction, the first support surface 21, 21 'having in the determined direction a sinusoidal shape with an alternation of curved convex sections (corresponding to the bosses 30) and concave curved sections (interleaved area which delimit the cavities 40).

With reference to Figure 3A and 3B it can be seen that the first portion 5 of the barrier envelope 2 matches the relief R of the first support surface 21 when the evacuation ceases. Arrows C of the figure 3B illustrate the shrinkage phenomenon of the porous material 3a. Under the effect of external pressure, a contraction is observed essentially along the two largest dimensions of the insulating core 1 (even when the relative shrinkage value is identical in the three dimensions, it is clear that the absolute value is much lower for the thickness). As the first portion 5 of the barrier envelope 2 conforms to the relief R, the rounded apex projections 5a are perfectly in correspondence with the bosses 30.

In a preferred embodiment, as clearly visible on the Figures 2A and 2B the relief R defines series S of cavities 40, which preferably extend in parallel like rows. The cavities 40 of the same series S are separated in pairs by a junction zone J having a convex curvature in at least one direction which makes it possible to progressively reduce the depth of each of the cavities 40 from a central zone 41. This central zone 41 corresponds to a maximum depth of the cavity 40 considered. When the relief R defines a regular mesh, preferably extending between two opposite ends 31, 32 of the panel 3, the first support surface 21 has corrugations in two transverse directions relative to each other.

With this configuration, the central zone 41 defines a center equidistant between four projections 30. The junction zones J between the cavities 40 form an intersection between two transverse (here perpendicular) profiles, one of which is a convex profile between two central zones 41 and the other is a concave profile between two adjacent bosses.

With reference to the figure 4 it is understood that the collars 10 formed by the first portion 5 of the barrier envelope 2 each coincide with one of the junction areas J. In the same way, the recesses 8 coincide obviously with the cavities 40 of the first support surface 21 .

sachant que h et λ sont exprimées en millimètres. On comprend que l'amplitude des ondulations 6 reste faible ou modérée (avec un rayon de courbure qui est suffisant et un caractère progressif des courbures respectives convexes et concaves). Les bossages 30 peuvent cependant présenter un profil non aplati (comme bien visible sur la figure 2B) en choisissant une amplitude h qui est supérieure ou égale à 0,5 mm (sans dépasser un seuil maximum qui est, de préférence, d'environ 2 mm). Sur la figure 2B, on comprend que les graduations de l'axe Z sont exprimées en millimètres.As visible on Figures 2A-3B the distance between the series S of cavities 40 is reduced and it is preferred that the spacing E between the series S be constant (it is a spacing E measured at Z = 0). Each of the cavities 40 here has a center 40a in the central zone 41, this center 40a corresponding to a local maximum depth as illustrated in FIGS. Figures 2A-2B and 3A . A gap λ is also provided which is constant here between the centers 40a of two adjacent cavities 40 separated by a boss 30. In a preferred embodiment, this spacing λ, measured along one direction (see X axis on the Figure 2A ) perpendicular to the direction used to measure the amplitude h, is such that the following relationship is satisfied: $$\mathrm{2}\le \mathrm{\lambda }/\mathrm{h}\le \mathrm{15}$$

knowing that h and λ are expressed in millimeters. It is understood that the amplitude of the corrugations 6 remains low or moderate (with a radius of curvature which is sufficient and a progressive character of respective curvatures convex and concave). The bosses 30 may, however, have a non-flattened profile (as clearly visible on the Figure 2B ) by choosing an amplitude h which is greater than or equal to 0.5 mm (without exceeding a maximum threshold which is preferably about 2 mm). On the Figure 2B it is understood that the graduations of the Z axis are expressed in millimeters.

In order to guide in a controlled manner the inflected zones of the first portion 5, the relief R of the first support surface 21 may advantageously have a sinusoidal structure along the two length and width axes of the panel 3, as illustrated in FIG. figure 4 . These two axes correspond to X and Y in the case of the Figure 2A . We then understand that the series S each extend in an intermediate general direction (typically at about 45 °) between the X and Y axes, in the plane defined by the two axes X and Y. A non-limiting example with two options of geometry is explained below.

Example

• option 1 avec une amplitude h de 1,72 mm et une longueur d'onde de 12,5 mm (λ = 12,5) ;
• option 2 correspondant à maillage encore plus serré, avec une amplitude h de 0,86 mm et une longueur d'onde de 6,3 mm (λ = 6,3).

In this example, consider the case of a commercially available insulating core 1, for example based on fumed silica, with a shrinkage of 4.5%. In the case of a relief R with a sinusoidal structure along the two axes length and width of the panel 3, the calculation to obtain a developed surface which has a similar excess (of 4.5%) with respect to the final apparent surface ( without taking into account the relief R) gave as result several options:

• Option 1 with an amplitude h of 1.72 mm and a wavelength of 12.5 mm (λ = 12.5);
• option 2 corresponding to mesh even tighter, with an amplitude h of 0.86 mm and a wavelength of 6.3 mm (λ = 6.3).

In these two options without any limiting character, the parameters of amplitude (difference between the upper level L3 and the lower level L1) and of wavelength are chosen identical in the two directions of the sinusoids (which corresponds to the non limiting the figure 4 ). The example shown on the Figure 2A is in accordance with option 1. Of course, the curvature of the bosses 30 may vary and the climax may be wider as in the example of FIG. Figure 2B (With a planar upper surface of small area, for example less than 1 mm ² , typically less than or equal to 0.49 mm ² and preferably less than or equal to 0.25 mm ² ). More generally, the wavelength, which corresponds to the distance between two vertices of adjacent bosses 30 of the same row, is here chosen less than 20 mm and preferably less than 10 mm. The amplitude h is here less than or equal to 2 mm for limit the local bending of the barrier envelope 2 and preferably it does not exceed 1 mm as in option 2 presented above.

Of course, the amplitude defined in a surface area may locally differ from another surface area in the support surface 21, 21 '. It is thus possible to provide slightly flatter areas alternating with areas whose relief is more accentuated. The wavelength λ can also vary in correspondence. These variations can be advantageously limited so that the ratio λ / h remains less than 15, and preferably less than 10.

It can be noted here that at the level Z = 0 in the case of the Figure 2A (Which makes it possible to define the level L2 of the necks 10 after application of the envelope 2), there is the separation between the bosses 30 and the cavities 40. The highest point of the boss 30 is at Z = +0.86 in FIG. Option 1, while center 40a is Z = - 0.86. The junction zone J with a convex curvature (in particular in the direction of the series S of cavities 40) then coincides with this level Z = 0. The junction zone J may however, in variants, be at a level different from the level Z = 0. Furthermore, it is understood that the cavities 40 may have a depth (along the Z axis) which is not equal to the height (along the Z axis) of the bosses 30. In fact, the slope may, where appropriate, be accentuated or reduced to form cavities 20.

Of course, other options may be used depending on the needs and / or depending on the nature of the porous material 3a. Two embodiments are reported here. A first variant concerns the shape of the hilly area. Although the double sine shape is preferred, different shapes can be applied with alternating troughs 8 and projections 5a. It is therefore possible to provide, where appropriate, curvatures that are different from that of a sinusoid, at least in the recesses 8 and / or in the collars 10. A second variant can take into account the case of the non-orthotropic porous materials 3 used to form the sinusoid. Insulating core 1. The geometry of the relief R is then adjusted to the mechanical behavior of the insulating core along the two axes (length and width) of its plane by choosing for each a wavelength, with a developed surface having the desired excess with respect to the apparent surface.

Of course, the options and variants mentioned above are not limited to the case of parallelepiped panels 3. The preparation of the relief on at least one of the main faces has no impact on the vacuuming process and the welding step of the envelope, so that the solution with the undulating on the one or more faces F1, F2 can be adapted to the case of curved panels or which have a particular geometry (here we can mention the case of panels with a central hole, used around a pipe or porthole). In any case, we prefer to use bosses 30 which cover at least 15%, and preferably at least 25%, of the apparent surface defined within the perimeter of the main face 4a.

A use of panels 3 provided with corrugations 6, in the field of thermally insulated enclosures, will now be described with reference to the figure 7 .

An enclosure 60, here of adiabatic type, serves to delimit the internal volume V of a refrigerator FR. At least two compartments may optionally be formed using separating partitions 59. The enclosure 60 is provided with cooling means 61, for example a refrigeration circuit. In a manner known per se, a compressor 61a and an evaporator 61b are in particular part of such a refrigeration circuit of the refrigerator FR.

The enclosure 60 has a bottom wall 62, a side wall (63a, 63b, 63c) which includes doors 63b, 63c preferably on the same side, and an upper wall 64. At least one panel 3 according to the The invention may extend behind the evaporator interface in a rear portion 63b of the side wall (63a, 63b, 63c). A complementary filling with a polyurethane foam may cover one side or extend along the panel 3 in the rear portion 63b.

At least one panel 3 is here inserted into the body of the doors 63b and 63c, which limits the thickness of each door while ensuring a very good coefficient of thermal insulation. A panel 3, 3 'can also be inserted internally into the body of the bottom wall 62 and the top wall 64. This optimizes the internal volume V can be loaded without increasing the external dimensions of the refrigerator FR. It may also be noted that at least one of the panels 3 'may have a curvature, here to follow the geometry of the bottom wall 62. It is preferable that the panels 3, 3' are arranged inside a corresponding wall body, to avoid degradation of the barrier envelope 2. Savings on the efficiency of the refrigerator FR can be obtained significantly with a panel 3, 3 'according to the invention. A gain of the order of 30% can be obtained for the FR refrigerator shown compared to a design without a PIV type panel in the walls. In addition, the surface characteristics of the panels 3, 3 'make it possible to guarantee that this gain (energy gain) is obtained durably.

Of course, it is possible to use panels 3 in an enclosure designed to maintain a temperature that is higher than the ambient environment and provided with heating means. Furthermore, other cooling applications are optimally satisfied with panels 3, 3 'according to the invention, for example refrigerated chambers of transport vehicles or cold storage rooms.

A use of panels 3 provided with corrugations 6, in the field of the building, will now be described in connection with the figure 8 .

The wall element 70 shown on the figure 8 is intended to double an interior partition of a building. At least one thermally insulating layer is formed by aligning rows of panels 3 according to the invention. A primary frame 74 makes it possible to integrate several panels 3 of the PIV type without associated mechanical protection, each having a parallelepipedal format, with the same thickness. The panels 3 are mounted on the primary framework 74 and distributed in a layer 69 of thermal insulation which has several rows of panels 3, here of the same width. In the example illustrated, the front faces of the panels F1 make it possible to constitute the front face of this layer, while a rear face oriented towards the wall 68 to be coated is formed by the faces F2 opposite to the faces F1 (a single layer of panels 3). We can of course also associate two layers of panels 3.

The wall 68 may be formed of bricks or blocks grouted. Here, the panels 3 are arranged in two rows and there is provided at least one intermediate support section 67b and support profiles 67a and 67c at the ends of the layer 69, which form part of the primary framework 74. The profiles 67a , 67b and 67c can be connected directly to the wall 68, for example by gluing or screwing, or kept parallel to the wall 68 indirectly (for example using studs, profiles, and / or spacers located behind layer 69 of panels 3). The intermediate profile 67b has an H profile and defines the junction between the first row and the second row of panels 3. The other sections 67a and 67c may have a U-shaped section. Each profile is preferably made in one piece and can provide a front anchor for receiving a spacer 75 used to space a facing 76. The facing 76 may typically be held by posts of a secondary frame (not shown). In this case one end of the spacers 75 can be connected in a fur or other system of fixing the amounts. More generally, it is understood that the panels 3 are associated with a rigid frame 72 which minimizes the distance between two adjacent panels 3 separated by a holding portion and support. This distance is typically less than 3 or 4 mm.

Preferably, the support profiles 67a, 67b, 67c consist of a single block made of plastic material, for example polyamide, PVC, polyurethane resin or based on composite materials, glass fibers, optionally with particles (for example polyamide PA 66 loaded with 25% glass fibers). A damping material, for example a foam, may be provided in the cavities receiving the slices of the panels 3, in order to minimize the friction with the projections 5a. The bosses 30 may be stretched in one direction to avoid concentrating the friction in a too localized area. Alternatively, it can be expected to form projections 5a rounded apex only in an area that does not coincide with the cavities of profiles 67a, 67b, 67c. In this case it is possible to provide a peripheral margin which does not exceed 30 or 40 mm in width and which has either a flatness or an alternation of planar zones and cavities spaced from each other and / or grooves. In an alternative, it is also possible to form a protective overlay only in the margin of at least one of the faces F1 and F2.

Each of the support profiles 67a, 67b, 67c here has a thermal conductivity less than or equal to 0.6 W m ^-1 K ^-1 and preferably less than 0.2 or 0.25 W m ^-1 K ^-1 . In order to minimize the heat conduction through the panel layer 3, a thermal conductivity less than or equal to 0.18 W m ^-1 K ^-1 is preferred for the material of the profiles 67a, 67b, 67c.

Of course, it is allowed to mix conventional PIV type panels with panels 3 according to the invention, in a wall element 70 for building. The wall element 70 is not necessarily limited to a partition lining: provision can be made to integrate at least one panel 3 in a floor module (inside caissons) or in a sub-layer protected by upper protection elements, rigid.

Applications for using panels 3 are not limited to storage, transport of temperature-sensitive materials, or wall insulation (walls, roof, floor) in buildings for which very long service lives are required. Panels 3 can be integrated in tanks or ice storage houses, vehicles, boats, submarines, truck trailers, freight cars, water heaters, heating and cooling ducts, tubes for storage and the transport of low boiling gas. In addition, the vacuum insulation panel 3 may advantageously be combined with a phase change material for storing thermal energy.

One of the advantages of the invention is to provide a panel 3 whose format can be completely similar to existing PIV panels, and whose longevity is improved. It may be noted that the method for designing the panels 3 is not complexified and the differences in height on the faces F1, F2 of the PIV-type panel 3 are sufficiently small (typically less than 2 or 3 mm of difference in elevation) in order not to cause discomfort for placement in thermal insulation applications. Of course, it is allowed to texture a single face of the panel 3, for example for applications that plan to drown on one side the panel 3 in a waterproof material to gases.

Improving the performance for the barrier effect can also result in the possibility of using a less high-end envelope 2 (less complex unitary films, less numerous, faster metallization), and therefore less expensive. This is the case of equipment such as refrigerators, freezers and hot water tanks.

It should be obvious to those skilled in the art that the present invention allows embodiments in many other specific forms without departing from the scope of the invention as claimed.

Claims (16)

Thermo-insulating panel (3, 3 ') of the PIV type, comprising: - a porous material (3a) resistant to compression, which defines two opposite major faces (4a, 4b) and whose smallest dimension is a maximum thickness (e) between these two faces; and a gas-tight barrier envelope (2) for maintaining an internal vacuum and containing the porous material (3a), the envelope being made from at least one flexible film or sheet and having: a first portion (5) covering a first of the two main faces, and a second portion (7) covering a second of the two main faces, a first support surface (21, 21 ') provided with a relief (R), underlying the first portion (5) of the barrier envelope (2); characterized in that the first support surface (21, 21 ') has corrugations (6) forming bosses (30) outwardly, each with a rounded apex,
and in that the barrier envelope (2) defines the outer layer of the atmospheric pressure panel (3, 3 '), the first portion (5) of the barrier envelope (2) extending along the first support surface and being deformed to conform to said relief (R) with projections (5a) rounded apex in correspondence with said bosses (30). Panel according to claim 1, wherein the first support surface (21, 21 ') has, in addition to the bosses (30), series (S) of cavities (40), two adjacent cavities of the same series (S ) intersecting with a junction zone (J) having a convex curvature in at least one direction that progressively reduces the depth of each of the cavities (40) from a central zone (41) that corresponds to a maximum depth of the cavity considered. Panel according to claim 1 or 2, wherein the barrier envelope (2) consists of a waterproof film whose thickness is less than 1 mm, the first portion (5) of the barrier envelope (2) defining the minus three surface levels (L1, L2, L3), with: - recesses (8) of a determined depth which coincide with cavities (40) of the first support surface (21, 21 '), which define the lower level (L1) of the three levels; - projections (5a) rounded apex, adjacent to the troughs (8) and separating two series (9) of troughs, which define the upper level (L3) of the three levels; and - Necks (10) shallower than the hollows (8), separating two projections (5a), and defining an intermediate level (L2) of the three levels. Panel according to claim 3, wherein the projections (5a) are flush at the same tangent plane (P), the first support surface (21, 21 ') defining: an apparent surface as perceived in two dimensions without taking into account the relief (R); and a developed surface that takes into account the relief (R); knowing that the developed surface is at least 2% greater than the apparent surface, and preferably greater than a percentage between 3 and 6% with respect to the apparent surface. Panel according to claim 3 or 4, wherein the difference between the upper level (L3) and the lower level (L1) is between 0.3 and 2 mm and is smaller than the spacing distance E between the respective vertices of two adjacent projections (5a). Panel according to claim 2 alone or in combination with one of claims 3 to 5, wherein each of the series (S) of cavities (40) extends in the same general direction, so that the bosses (30) are distributed staggered and the cavities (40) are distributed in staggered rows. Panel according to Claim 2 alone or in combination with one of Claims 3 to 6, in which the two main faces (4a, 4b) are parallel and each of the cavities (40) has a center (40a) corresponding to a local maximum of depth, the first support surface (21, 21 ') satisfying the following relation: $$\mathrm{2}\le \mathrm{\lambda }/\mathrm{h}\le \mathrm{15}$$

or
h represents a maximum amplitude of the relief (R) measured perpendicularly to the two main faces (4a, 4b) and expressed in millimeters, and
λ represents a spacing between two centers (40a) of cavities (40) adjacent separated by a boss, this spacing, which is preferably constant, being expressed in millimeters, measured in a direction which is perpendicular to the direction used to measure the amplitude h. Panel according to any one of the preceding claims, wherein the first support surface (21, 21 ') extends between two opposite ends (31, 32) of the panel (3), the bosses (30) being distributed in such a way the relief (R) extends between said two opposite ends of the panel. Panel according to any one of the preceding claims, wherein the bosses (30) are distributed in rows, in a determined direction, the first support surface (21, 21 ') having in said determined direction a sinusoidal shape with alternation of curved convex sections and concave curved sections. Panel according to any one of claims 1 to 9, wherein the first support surface (21) is defined by at least one of the two main faces (4a, 4b) of the porous material (3a). A panel according to any one of claims 1 to 9, wherein the first support surface (21 ') is defined by an intermediate layer (26) distinct from the porous material and thinner than the porous material (3a). Panel according to any one of the preceding claims, wherein the first support surface (21, 21 ') has corrugations in two directions transverse to each other. Panel according to one of the preceding claims, comprising a second support surface (23) provided with a relief, underlying the second portion (7) of the barrier envelope (2), each of the first and second surfaces with no planar surfaces, the panel (3) having a parallelepipedal format, preferably of rectangular section. A method of manufacturing a PIV type thermal insulation board (3) according to any one of the preceding claims, using a plate of porous material (3a) resistant to compression and comprising the steps consisting essentially of: forming a first support surface (21, 21 ') with a relief (R), by transcribing a relief with corrugations present on a plate or a roll, so that the first support surface has bosses (30); outwardly, each with a rounded apex, the first support surface being selected from a surface of a main face (4a, 4b) of the porous material plate (3a), and a major surface of an intermediate layer (26) distinct from the porous material; - during evacuation posterior to the formation of the relief (R), wrap the plate of porous material (3a) and cover the first support surface (21, 21 '), directly or indirectly, by a barrier envelope (2) gastight to maintain an interior vacuum; and - subject the outside of the envelope to atmospheric pressure, thanks to a portion (5) of the barrier envelope (2) extends along the first support surface (21, 21 ') and conforms to a relief with undulations (6) resulting from contact with the relief (R) to form a main face (F1, F2) of the panel (3) provided with projections (5a). Thermally insulating wall element (70) for building, characterized in that it comprises a plurality of panels (3) according to one of claims 1-13 glued or secured by means of a rigid frame (72) in the least one thermal insulation layer (69). Enclosure (60) provided with means for cooling (61) or heating, for thermally insulating an interior volume (V), comprising a bottom wall (62), a side wall (63a, 63b, 63c) and a top wall (64), characterized in that it comprises at least one panel (3) according to one of the claims 1-13 forming part of one wall of the bottom wall (62), the side wall (63a, 63b, 63c) and the top wall (64).

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